Yaacov Herzig

The kinetics of inhibition of human acetylcholinesterase and butyrylcholinesterase by two series of novel carbamates

Controlled inhibition of brain acetyl- and butyrylcholinesterases (AChE and BChE, respectively) and of monoamine oxidase-B (MAO-B) may slow neurodegeneration in Alzheimers and Parkinsons diseases. It was postulated that certain carbamate esters would inhibit AChE and BChE with the concomitant release in the brain of the OH-derivatives of rasagiline or selegiline that can serve as inhibitors of MAO-B and as antioxidants. We conducted a detailed in vitro kinetic study on two series of novel N-methyl, N-alkyl carbamates and compared them with rivastigmine, a known anti-Alzheimer drug. The rates of carbamylation (ki) and decarbamylation (kr) of recombinant human AChE were mainly determined by the size of the N-alkyl substituent and to a lesser extent by the nature of the leaving group. ki was highest when the alkyl was methyl, hexyl, cyclohexyl, or an aromatic substituent and lowest when it was ethyl. This suggested that ki depends on a delicate balance between the length of the residue and its degree of freedom of rotation. By contrast, presumably because of its wider gorge, inhibition of human BChE was less influenced by the size of the alkyl group and more dependent on the structure of the leaving group. The data show how the degree of enzyme inhibition can be manipulated by structural changes in the N-methyl, N-alkyl carbamates and the corresponding leaving group to achieve therapeutic levels of brain AChE, BChE, and MAO-B inhibition.

Pharmacokinetic Analysis and Antiepileptic Activity of Tetra-Methylcyclopropane Analogues of Valpromide

AbstractPurpose. The described structure pharmacokinetic pharmacodynamic relationships (SPPR) study explored the utilization of tetramethylcyclopropane analogues of valpromide (VPD), or tetra-methylcyclopropane carboxamide derivatives of valproic acid (VPA) as new antiepileptics. Methods. The study was carried out by investigating the pharmacokinetics in dogs and pharmacodynamics (anticonvulsant activity and neurotoxicity) of the following three cyclopropane analogues of VPD: 2,2,3,3-tetramethylcyclopropane carboxamide (TMCD), N-methyl TMCD (M-TMCD) and N-[(2,2,3,3-tetramethylcyclopropyl)carbonyl]-glycinamide (TMC-GLD). Results. The three investigated compounds showed a good anticonvulsant profile in mice and rats due to the fact that they were metabolically stable VPD analogues which were not biotransformed to their non-active acid, 2,2,3,3-tetramethylcyclopropane carboxylic acid (TMCA). M-TMCD was metabolized to TMCD and TMC-GLD underwent partial biotransformation to its glycine analogue N-[(2,2,3,3-tetramethylcyclopropyl)carbonyl]-glycine (TMC-GLN). Unlike TMC-GLN, the above mentioned amides had low clearance and a relatively long half life. Conclusions. In contrast to VPD which is biotransformed to VPA, the aforementioned cyclopropane derivatives were found to be stable to amide-acid biotransformation. TMCD and M-TMCD show that cyclic analogues of VPD, like its aliphatic isomers, must have either two substitutions at the β position to the carbonyl, such as in the case of TMCD, or a substitution in the α and in the β positions like in the VPD isomer, valnoctamide (VCD). This paper discusses the antiepileptic potential of tetramethylcyclopropane analogues of VPD which are in animal models more potent than VPA and may be non-teratogenic and non-hepatotoxic.

Pharmacokinetic and pharmacodynamic analysis of (E)-2-ene valproyl derivatives of glycine and valproyl derivatives of nipecotic acid

GABA is a major inhibitory neurotransmitter in mammals, whose uptake in glial cells is inhibited by nipecotic acid. In addition to GABA, glycine is an important inhibitory neurotransmitter. Valproic acid (VPA) is one of the four established antiepileptics and (E)-2-ene valproic acid ((E)-2-ene VPA) is its major active metabolite. The described structure-pharmacokinetic-pharmacodynamic relationship (SPPR) study explored the possibility of utilizing valproyl derivatives of glycine and nipecotic acid as new antiepileptics. The pharmacokinetics and pharmacodynamics (anticonvulsant activity and neurotoxicity) of the following conjugation products were investigated: (E)-2-ene valproyl glycinamide (between (E)-2-ene VPA and glycinamide) and valproyl nipecotic acid and valproyl nipecotamide (between VPA and nipecotic acid). Out of the investigated compounds only (E)-2-ene valproyl glycinamide showed a good anticonvulsant profile in both mice and rats due to its better pharmacokinetic and pharmacodynamic profile. (E)-2-ene valproyl glycinamide was more potent than VPA and showed an activity and a safety margin similar to those of its analogous compound valproyl glycinamide. The investigated valproyl derivatives did not operate as chemical drug delivery systems (CDDSs) of glycine or nipecotic acid, but, rather, acted as drugs on their own. (E)-2-ene valproyl glycinamide was partially excreted unchanged in the urine (fe = 7.4%), while its urinary metabolite was (E)-2-ene valproyl glycine. Unlike the new antiepileptic tiagabine, in which nipecotic acid is attached to 4, 4-di-(3-methylthien-2-yl)-3-butenyl and yields an active compound, the conjugation between nipecotic acid or its amide and VPA yielded inactive entities. In contrast to nipecotic acid, the conjugation between VPA or (E)-2-ene VPA and glycinamide gave two active compounds with similar pharmacokinetic and pharmacodynamic profiles.